Nickel nanoparticle functionalized amine-modified fibrous hierarchical zeolite and method of making the same

ABSTRACT

A functionalized fibrous hierarchical zeolite includes a framework comprising aluminum atoms, silicon atoms, and oxygen atoms, the framework further comprising a plurality of micropores and a plurality of mesopores. The functionalized fibrous hierarchical zeolite is functionalized with at least one amine. A plurality of nanoparticles comprising nickel are immobilized on the framework.

TECHNICAL FIELD

The present disclosure generally relates to porous materials and, more specifically, to zeolites.

BACKGROUND

Materials that include pores, such as zeolites, may be utilized in many petrochemical industrial applications. For example, such materials may be utilized as catalysts in a number of reactions which convert hydrocarbons or other reactants from feed chemicals to product chemicals. Zeolites may be characterized by a microporous structure framework type. Various types of zeolites have been identified over the past several decades, where zeolite types are generally described by framework types, and where specific zeolite materials may be more specifically identified by various names such as ZSM-5 or beta-zeolite.

BRIEF SUMMARY

The present application is directed to functionalized amine-modified zeolites. Such functionalized amine-modified zeolites may, according to various embodiments, include nickel nanoparticle functionalization. Such functionalized amine-modified zeolites, according to one or more embodiments presently disclosed, may have enhanced or differentiated catalytic functionality as compared to conventional zeolites. Additionally or alternatively, the functionalized amine-modified zeolites may be useful as zeolite substrates upon which additional chemical transformations may take place.

In accordance with one or more embodiments of the present disclosure, a functionalized fibrous hierarchical zeolite includes a framework comprising aluminum atoms, silicon atoms, and oxygen atoms, the framework further comprising a plurality of micropores and a plurality of mesopores. The functionalized fibrous hierarchical zeolite is functionalized with at least one amine. A plurality of nanoparticles comprising nickel are immobilized on the framework.

In accordance with one or more embodiments of the present disclosure, a method for making a functionalized fibrous hierarchical zeolite comprising a plurality of nanoparticles comprising nickel includes contacting a fibrous hierarchical zeolite with an organometallic complex comprising a nickel atom. The fibrous hierarchical zeolite includes a framework comprising aluminum atoms, silicon atoms, and oxygen atoms, the framework further comprising a plurality of micropores and a plurality of mesopores, the fibrous hierarchical zeolite being functionalized with at least one amine. The nanoparticles comprising nickel are immobilized on the framework. The contacting of the fibrous hierarchical zeolite with the organometallic complex forms the functionalized fibrous hierarchical zeolite comprising a plurality of nanoparticles comprising nickel.

Additional features and advantages of the described embodiments will be set forth in the detailed description, which follows, and in part will be readily apparent to those skilled in the art from that description or recognized by practicing the described embodiments, including the detailed description which follows, the claims, as well as the appended drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The following detailed description of specific embodiments of the present disclosure can be best understood when read in conjunction with the following drawings, where like structure is indicated with like reference numerals and in which:

Figure (FIG. 1 provides an exemplary reaction scheme to produce the nickel-nanoparticle functionalized amine-modified zeolite;

FIG. 2 provides the magic angle spinning ²⁷Al solid state Nuclear Magnetic Resonance (NMR) spectrum of a nickel-containing organometallic functionalized amine-modified ZSM-5 zeolite;

FIG. 3 provides the particle size distribution of the nickel-nanoparticles;

FIG. 4 provides scanning transmission electron microscopy images of a nickel-nanoparticle functionalized amine-modified ZSM-5 zeolite;

FIG. 5 provides the X-ray photoelectron spectroscopy of a nickel-nanoparticle functionalized amine-modified ZSM-5 zeolite; and

FIG. 6 provides transmission electron microscopy images of a nickel-nanoparticle functionalized amine-modified ZSM-5 zeolite.

Reference will now be made in greater detail to various embodiments, some embodiments of which are illustrated in the accompanying drawings. Whenever possible, the same reference numerals will be used throughout the drawings to refer to the same or similar parts.

DETAILED DESCRIPTION

The present disclosure is directed to amine-modified zeolites which are modified by the inclusion of nickel nanoparticle functionalization. According to embodiments disclosed herein, the functionalized amine-modified zeolites may be formed by a process that includes dehydroxylating an initial zeolite, modifying the dehydroxylated zeolite to include amine functionality, and forming the nickel nanoparticle functionalized zeolite from the amine-modified zeolite. While embodiments of functionalized amine-modified zeolites prepared by this procedure are disclosed herein, embodiments of the present disclosure should not be considered to be limited to zeolites made by such a process.

As presently described, “initial” zeolites (which in some embodiments may be hierarchical mesoporous zeolites) may be supplied or produced, as is presently disclosed. As described herein, the characterization of the structure and material of the zeolite may apply to the initial zeolite as well as the dehydroxylated zeolite and/or amine-modified zeolite and/or the functionalized zeolite. In one or more embodiments, the structure and material composition of the initial zeolite does not substantially change through the dehydroxylation and/or functionalization steps (aside from the described functionalities formed by the dehydroxylation and/or amine modification and/or nickel nanoparticle functionalization steps). For example, the framework type and general material constituents of the framework may be substantially the same in the initial zeolite and the functionalized amine-modified zeolite aside from the addition of the nickel nanoparticles. Additionally, the mesoporosity of the initial zeolite may be carried into the functionalized amine-modified zeolite. Accordingly, when a “zeolite” is described herein with respect to its structural characterization, the description may refer to the initial zeolite, the dehydroxylated zeolite, the amine-modified zeolite, and/or the nickel nanoparticle functionalized amine-modified zeolite.

As used throughout this disclosure, “zeolites” may refer to micropore-containing inorganic materials with regular intra-crystalline cavities and channels of molecular dimension. Zeolites generally comprise a crystalline structure, as opposed to an amorphous structure such as what may be observed in some porous materials such as amorphous silica. Zeolites generally include a microporous framework which may be identified by a framework type. The microporous structure of zeolites (e.g., 0.3 nm to 2 nm pore size) may render large surface areas and desirable size-/shape-selectivity, which may be advantageous for catalysis. The zeolites described may include, for example, aluminosilicates, titanosilicates, or pure silicates. In embodiments, the zeolites described may include micropores (present in the microstructure of a zeolite), and additionally include mesopores. As used throughout this disclosure, micropores refer to pores in a structure that have a diameter of greater than or equal to 0.1 nm and less than or equal to 2 nm, and mesopores refer to pores in a structure that have a diameter of greater than 2 nm and less than or equal to 50 nm. Unless otherwise described herein, the “pore size” of a material refers to the average pore size, but materials may additionally include micropores and/or mesopores having a particular size that is not identical to the average pore size.

Generally, zeolites may be characterized by a framework type which defines their microporous structure. The zeolites described presently, in one or more embodiments, are not particularly limited by framework type. Framework types are described in, for example, “Atlas of Zeolite Framework Types” by Ch. Baerlocher et al, Fifth Revised Edition, 2001, which is incorporated by reference herein. In embodiments, the zeolites may comprise microstructures (which include micropores) characterized as, among others, *BEA framework type zeolites (such as, but not limited to, zeolite Beta), FAU framework type zeolites (such as, but not limited to, zeolite Y), MOR framework type zeolites, or MFI framework type zeolite (such as, but not limited to, ZSM-5). It should be understood that *BEA, MFI, MOR, and FAU refer to zeolite framework types as identified by their respective three letter codes established by the International Zeolite Association (IZA). Other framework types are contemplated in the presently disclosed embodiments.

In one or more embodiments, the zeolite may comprise an aluminosilicate microstructure. The zeolite may comprise at least 99 wt. % of the combination of silicon atoms, oxygen atoms, and aluminum atoms. The molar ratio of Si/Al may be from 2 to 100, such as from 2 to 25, from 25 to 50, from 50 to 75, from 75 to 100, or any combination of these ranges.

In one or more embodiments, the zeolite may be an MFI framework type zeolite, such as a ZSM-5. “ZSM-5” generally refers to zeolites having an MFI framework type according to the IZA zeolite nomenclature and comprising mostly silica and alumina, as is understood by those skilled in the art. ZSM-5 refers to “Zeolite Socony Mobil-5” and is a pentasil family zeolite that can be represented by the chemical formula Na_(n)Al_(n)Si₉₆-nO₁₉₂.16H₂O, where 0<n<27. According to one or more embodiments, the molar ratio of silica to alumina in the ZSM-5 may be at least 5. For example, the molar ratio of silica to alumina in the ZSM-5 zeolite may be at least 10, at least 12, or even at least 30, such as from 5 to 30, from 12 to 30, from 5 to 80, from 5 to 300, from 5 to 1000, or even from 5 to 1500. Examples of suitable ZSM-5 zeolite include those commercially available from Zeolyst International, such as CBV2314, CBV3024E, CBV5524G, and CBV28014, and from TOSOH Corporation, such as HSZ-890 and HSZ-891.

In one or more embodiments, the zeolite may comprise an FAU framework type zeolite, such as zeolite Y or ultra-stable zeolite Y (USY). As used herein, “zeolite Y” and “USY” refer to a zeolite having a FAU framework type according to the IZA zeolite nomenclature and comprising mostly silica and alumina, as would be understood by one skilled in the art. In one or more embodiments, USY may be prepared from zeolite Y by steaming zeolite Y at temperatures above 500° C. The molar ratio of silica to alumina may be at least 3. For example, the molar ratio of silica to alumina in the zeolite Y may be at least 5, at least 12, at least 30, or even at least 200, such as from 5 to 200, from 12 to 200, or from about 15 to about 200. The unit cell size of the zeolite Y may be from about 24 Angstrom to about 25 Angstrom, such as 24.56 Angstrom.

In one or more embodiments, the zeolite may comprise a *BEA framework type zeolite, such as zeolite Beta. As used in this disclosure, “zeolite Beta” refers to a zeolite having a *BEA framework type according to the IZA zeolite nomenclature and comprising mostly silica and alumina, as would be understood by one skilled in the art. The molar ratio of silica to alumina in the zeolite Beta may be at least 10, at least 25, or even at least 100. For example, the molar ratio of silica to alumina in the zeolite Beta may be from 5 to 500, such as from 25 to 300.

In embodiments, the initial zeolites may include well-defined isolated silanol groups and not completely lose Brønsted acid sites upon dehydroxylation at high temperatures.

Along with micropores, which may generally define the framework type of the zeolite, the zeolites may also comprise mesopores. As a result of having more than one type of pore, the zeolites used in certain embodiments herein may be referred to as “hierarchical zeolites.” As used herein a “mesoporous zeolite” refers to a zeolite which includes mesopores, and may have an average pore size of from 2 to 50 nm. The presently disclosed hierarchical zeolites may have an average pore size of greater than 2 nm, such as from 4 nm to 16 nm, from 6 nm to 14 nm, from 8 nm to 12 nm, or from 9 nm to 11 nm. In some embodiments, the majority of the mesopores may be greater than 8 nm, greater than 9 nm, or even greater than 10 nm. The mesopores of the hierarchical zeolites described may range from 2 nm to 40 nm, and the median pore size may be from 8 nm to 12 nm. In embodiments, the mesopore structure of the zeolites may be fibrous, where the mesopores are channel-like. As described herein, “fibrous zeolites” may comprise reticulate fibers with interconnections and have a dense inner core surrounded by less dense outer fibers. Generally, fibrous zeolites may comprise intercrystalline voids between the fibers where the voids between the less dense, outer fibers are mesopore sized and give the fibrous zeolite its mesoporosity. The hierarchical zeolites described may be generally silica-containing materials, such as aluminosilicates, pure silicates, or titanosilicates. It should be understood that while hierarchical zeolites are referenced in one or more portions of the present disclosure, some zeolites may not be mesoporous. For example, some embodiments may utilize zeolites which have an average pore size of less than 2 nm, or may not have mesopores in any capacity.

The hierarchical zeolites described in the present disclosure may have enhanced catalytic activity as compared to non-mesoporous zeolites. Without being bound by theory, it is believed that the microporous structures provide for the majority of the catalytic functionality of the hierarchical zeolites described. The mesoporosity may additionally allow for greater catalytic functionality because more micropores are available for contact with the reactant in a catalytic reaction. The mesopores generally allow for better access to microporous catalytic sites on the hierarchical zeolite, especially when reactant molecules are relatively large. For example, larger molecules may be able to diffuse into the mesopores to contact additional catalytic microporous sites. Additionally, mesoporosity may allow for additional grafting sites on the zeolite where organometallic moieties may be bound.

In embodiments, the hierarchical zeolites may have a surface area of greater than or equal to 300 m²/g, greater than or equal to 350 m²/g, greater than or equal to 400 m²/g, greater than or equal to 450 m²/g, greater than or equal to 500 m²/g, greater than or equal to 550 m²/g, greater than or equal to 600 m²/g, greater than or equal to 650 m²/g, or even greater than or equal to 700 m²/g, and less than or equal to 1,000 m²/g. In one or more other embodiments, the hierarchical zeolites may have pore volume of greater than or equal to 0.2 cm³/g, greater than or equal to 0.25 cm³/g, greater than or equal to 0.3 cm³/g, greater than or equal to 0.35 cm³/g, greater than or equal to 0.4 cm³/g, greater than or equal to 0.45 cm³/g, greater than or equal to 0.5 cm³/g, greater than or equal to 0.55 cm³/g, greater than or equal to 0.6 cm³/g, greater than or equal to 0.65 cm³/g, or even greater than or equal to 0.7 cm³/g, and less than or equal to 1.5 cm³/g. In further embodiments, the portion of the surface area contributed by mesopores may be greater than or equal to 20%, greater than or equal to 25%, greater than or equal to 30%, greater than or equal to 35%, greater than or equal to 40%, greater than or equal to 45%, greater than or equal to 50%, greater than or equal to 55%, greater than or equal to 60%, or even greater than or equal to 65%, such as between 20% and 70% of total surface area. In additional embodiments, the portion of the pore volume contributed by mesopores may be greater than or equal to 20%, greater than or equal to 30%, greater than or equal to 35%, greater than or equal to 40%, greater than or equal to 45%, greater than or equal to 50%, greater than or equal to 55%, greater than or equal to 60%, greater than or equal to 65%, greater than or equal to 70%, or even greater than or equal to 75%, such as between 20% and 80% of total pore volume. Surface area, average pore size, and pore volume distribution may be measured by N₂ adsorption isotherms performed at 77 Kelvin (K) (such as with a Micrometrics ASAP 2020 system). As would be understood by those skilled in the art, Brunauer-Emmett-Teller (BET) analysis methods may be utilized.

The hierarchical zeolites described may form as particles that may be generally spherical in shape or irregular globular shaped (that is, non-spherical). In embodiments, the particles have a “particle size” measured as the greatest distance between two points located on a single zeolite particle. For example, the particle size of a spherical particle would be its diameter. In other shapes, the particle size is measured as the distance between the two most distant points of the same particle when viewed in a microscope, where these points may lie on outer surfaces of the particle. The particles may have a particle size from 25 nm to 900 nm, from 25 nm to 800 nm, from 25 nm to 700 nm, from 25 nm to 600 nm, from 25 nm to 500 nm, from 50 nm to 400 nm, from 100 nm to 300 nm, or less than 900 nm, less than 800 nm, less than 700 nm, less than 600 nm, less than 500 nm, less than 400 nm, less than 300 nm, or less than 250 nm. Particle sizes may be determined by visual examination under a microscope.

The hierarchical zeolites described may be formed in a single-crystal structure, or if not single crystal, may be comprised of a limited number of crystals, such as 2, 3, 4, or 5. The crystalline structure of the hierarchical zeolites may have a branched, fibrous structure with highly interconnected intra-crystalline mesopores. Such structures may be advantageous in applications where the structural integrity of the zeolite is important while the ordering of the mesopores is not.

According to one or more embodiments, the hierarchical zeolites described in the present disclosure may be produced by utilizing cationic polymers, as is subsequently described in the present disclosure, as structure-directing agents. The cationic polymers may function as dual-function templates for synthesizing the hierarchical zeolites, meaning that they act simultaneously as a template for the fabrication of the micropores and as a template for the fabrication of the mesopores.

According to various embodiments, the hierarchical zeolites described in the present disclosure may be produced by forming a mixture comprising the cationic polymer structure-directing agent (SDA), such as poly(N¹,N¹-diallyl-N¹-methyl-N⁶,N⁶,N⁶-tripropylhexane-1,6-diamonium bromide), referred to as (PDAMAB-TPHAB) and shown in formula (1), and one or more precursor materials, which will form the structure of the hierarchical zeolites. The precursor materials may contain the materials that form the porous structures, such as alumina and silica for an aluminosilicate zeolite, titania and silica for a titanosilicate zeolite, and silica for a pure silica zeolite. For example, the precursor materials may be one or more of a silicon-containing material, a titanium-containing material, and an aluminum-containing material. For example, at least NaAlO₂, tetraethylorthosilicate, and the cationic polymer may be mixed in an aqueous solution to form an intermediate material that will become a mesoporous aluminosilicate zeolite. It should be appreciated that other precursor materials that include silica, titania, or alumina may be utilized. For example, in other embodiments, tetraethylorthosilicate and cationic polymers may be combined to form an intermediate material that will become a silicate hierarchical zeolite; or tetra-ethylorthosilicate, tetrabutylorthotitanate, and cationic polymer may be combined to form an intermediate material that will become a titanosilicate hierarchical zeolite. Optionally, the combined mixture may be heated to form the intermediate material, and may crystallize under autoclave conditions. The intermediate material may comprise micropores, and the cationic polymer may act as a structure-directing agent in the formation of the micropores during crystallization. The intermediate materials may still contain the cationic polymers which may at least partially define the space of the mesopores following their removal. The products may be centrifuged, washed, and dried, and finally, the polymer may be removed by a calcination step. The calcination step may comprise heating at temperatures of at least about 400° C., 500° C., 550° C., or even greater. Without being bound by theory, it is believed that the removal of the polymers forms at least a portion of the mesopores of the hierarchical zeolite, where the mesopores are present in the space once inhabited by the polymers.

The precursor materials of the mixture, or reagents of the sol-gel, generally determine the material composition of the hierarchical zeolites, such as an aluminosilicate, a titanosilicate, or a pure silicate. An aluminosilicate hierarchical zeolite may comprise a molar ratio of Si/Al of from 2 to 10,000, from 25 to 10,000, from 50 to 10,000, from 100 to 10,000, from 200 to 10,000, from 500 to 10,000, from 1,000 to 10,000, or even from 2,000 to 10,000. In a pure silicate zeolite, a negligible amount or no amount of aluminum is present in the framework of the zeolite, and the Si/Al molar ratio theoretically approaches infinity. As used herein a “pure silicate” refers to a material comprising at least about 99.9 weight percent (wt. %) of silicon and oxygen atoms in the framework of the zeolite. Other materials, including water and sodium hydroxide, may be utilized during the formation of the material but are not present in the framework of the zeolite. A pure silica hierarchical zeolite may be formed by utilizing only silicon-containing materials to form the framework of the zeolite and no aluminum. A titanosilicate porous structure may comprise a molar ratio of Si/Ti of from 30 to 10,000, from 40 to 10,000, from 50 to 10,000, from 100 to 10,000, from 200 to 10,000, from 500 to 10,000, from 1,000 to 10,000, or even from 2,000 to 10,000. It has been found that PDAMAB-TPHAB cationic polymer, described herein, may be utilized to form mesoporous ZSM-5 zeolites when used with silica and alumina precursor materials, mesoporous TS-1 zeolites when used with a silica and titania precursor, and mesoporous silicalite-I zeolites when used with silica precursors. It has also been found that PDAMAB-TMHAB may be utilized to form mesoporous Beta zeolites when used with silica and alumina precursors.

The cationic polymers presently disclosed may comprise one or more monomers which each comprise multiple cationic functional groups, such as quaternary ammonium cations or quaternary phosphonium cations. The cation functional groups of the monomers may be connected by a hydrocarbon chain. Without being bound by theory, it is believed that the cationic functional groups may form or at least partially aid in forming the microstructure of the hierarchical zeolite (for example, an MFI framework type or BEA framework type) and the hydrocarbon chains and other hydrocarbon functional groups of the polymer may form or at least partially aid in forming the mesopores of the hierarchical zeolite.

The cationic polymers may comprise functional groups, which are utilized as SDAs for the fabrication of the zeolite microstructure. Such functional groups, which are believed to form the zeolite microstructure, include quaternary ammonium cations and quaternary phosphonium cations. Quaternary ammonium is generally depicted in formula (2) and quaternary phosphonium is generally depicted in formula (3).

As used throughout this disclosure, the encircled plus symbols (“+”) show cationic positively charged centers. One or more of the various R groups may be structurally identical or may be structurally different from one another. In formula (2) and formula (3), R₁, R₂, R₃, and R₄ may include hydrogen atoms or hydrocarbons, such as a hydrocarbon chain, optionally comprising one or more heteroatoms. As used throughout this disclosure, a “hydrocarbon” refers to a chemical or chemical moiety comprising hydrogen and carbon. For example, the hydrocarbon chain may be branched or unbranched, and may comprise an alkane hydrocarbon chain, an alkene hydrocarbon chain, or an alkyne hydrocarbon chain, including cyclic or aromatic moieties. In some embodiments, one or more of R₁, R₂, R₃, and R₄ may represent hydrogen atoms. As used throughout this disclosure, a heteroatom is a non-carbon and non-hydrogen atom. In embodiments, quaternary ammonium and quaternary phosphonium may be present in a cyclic moiety, such as a five-atom ring, a six-atom ring, or a ring comprising a different number of atoms. For example, in formula (2) and formula (3), the R₁ and R₂ constituents may be part of the same cyclic moiety.

In one or more embodiments, the two cation moieties may form ionic bonds with anions. Various anionic chemical species are contemplated, including Cl⁻, Br⁻, F⁻, I⁻, ⁻OH, ½ SO₄ ²⁻, ⅓ PO₄ ³⁻, ½ S²⁻, AlO₂ ⁻, BF₄ ⁻, SbF₆ ⁻, and B[3,5-(CF₃)₂C₆H₃]₄ ⁻ (commonly referred to as “BArF”). In some embodiments, an anion with a negative charge of more than 1⁻, such as 2⁻, 3⁻, or 4⁻, may be utilized, and in those embodiments, a single anion may pair with multiple cations of the cationic polymer. As used throughout this disclosure, a fraction listed before an anionic composition means that the anion is paired with more than one cation and may, for example, be paired with the number of cations equal to its negative charge.

In one or more embodiments, a hydrocarbon chain may separate two cations of a monomer from one another. As described above, the hydrocarbon chain may be branched or unbranched, and may comprise an alkane hydrocarbon chain, an alkene hydrocarbon chain, or an alkyne hydrocarbon chain, including cyclic or aromatic moieties. In one embodiment, the length of the hydrocarbon chain (measured as the number of carbons in the chain directly connecting the two cations) may be from 1 to 10,000 carbon atoms, such 1 to 20 carbon atom alkane chains.

The cationic polymers described in this disclosure are generally non-surfactants. A surfactant refers to a compound that lowers the surface tension (or interfacial tension) between two liquids or between a liquid and a solid, usually by the inclusion of a hydrophilic head and a hydrophobic tail. Non-surfactants do not contain such hydrophobic and hydrophilic regions, and do not form micelles in a mixture containing a polar material and non-polar material. Without being bound by theory, it is believed that the polymers described are non-surfactants because of the inclusion of two or more cation moieties, which are joined by a hydrocarbon chain. Such an arrangement has polar charges on or near each end of the monomer, and such an arrangement excludes the hydrophobic segment from the polymer, and thus limits the surfactant behavior (self-assembly in solution). On the atomic scale, it is believed that the functional groups (for example, quaternary ammoniums) on the polymer direct the formation of zeolite structure; on the mesoscale, the polymer functions simply as a “porogen” rather than a structure directing agent in the conventional sense. As opposed to the cases of surfactants, non-surfactant polymers do not self-assemble to form an ordered meso-structure, which in turn favors the crystallization of zeolites, producing a new class of hierarchical zeolites that feature three-dimensionally (3-D) continuous zeolitic frameworks with highly interconnected intracrystalline mesopores.

In one embodiment, the cationic polymer may comprise the generalized structure depicted in formula (4):

Formula (4) depicts a single monomer of the cationic polymer, which is signified by the included bracket, where n is the total number of repeating monomers in the polymer. In some embodiments, the cationic polymer may be a copolymer comprising two or more monomer structures. The X and Y of formula (4) independently represent anions, such as Cl⁻, Br⁻, F⁻, I⁻, ⁻OH, ½ SO₄ ²⁻, ⅓ PO₄ ³⁻, ½ S²⁻, AlO₂ ⁻, BF₄ ⁻, SbF₆ ⁻, and B[3,5-(CF₃)₂C₆H₃]₄ ⁻. In some embodiments, an anion with a negative charge of more than 1⁻, such as 2⁻, 3⁻, or 4⁻, may be utilized, and in those embodiments, a single anion may pair with multiple cations of the cationic polymer of formula (4). It should be understood that one or more monomers (such as that shown in formula (4)) of the cationic polymers described in the present application may be different from one another. For example, various monomer units may include different R groups. Referring to formula (4), A and B may independently represent nitrogen or phosphorus. In one embodiment, A and B may both be nitrogen. In one embodiment, A may be nitrogen and B may be phosphorus. In one embodiment, A may be phosphorus and B may be nitrogen. In another embodiment, A and B may both be phosphorus. For example, A may comprise a quaternary ammonium cation or a quaternary phosphonium cation, and B may comprise a quaternary ammonium cation or a quaternary phosphonium cation. As shown in formula (4), A may be a portion of a ring structure, such as a five-membered ring. R₅ may be a branched or unbranched hydrocarbon chain, optionally further including at least one heteroatom, having a carbon chain length of from 1 to 10,000 carbon atoms, such as a 2 to 20 carbon alkane, and R₆, R₇, R₈, R₉, R₁₀, R₁₁, R₁₂, and R₁₃ may independently be a hydrogen atom or a hydrocarbon optionally comprising one or more heteroatoms. For example, one or more of R₆, R₇, R₈, R₉, R₁₀, R₁₁, R₁₂, and R₁₃ may independently be hydrogen or an alkyl group, such as a methyl group, an ethyl group, a propyl group, a butyl group, or a pentyl group. In embodiments, one or more of R₆, R₇, R₈, and R₉ may be hydrogen. In embodiments, one or more of R₁₀, R₁₁, R₁₂, and R₁₃ may be the same or different and may be an alkyl group. For example, R₁₀ may be a methyl, an ethyl, a propyl, or a butyl group, and one or more of R₁₁, R₁₂, and R₁₃ may independently be a methyl, an ethyl, a propyl, or a butyl group. In one embodiment, R₁₀ is a methyl group and R₁₁, R₁₂, and R₁₃ are all propyl groups. In one embodiment, R₁₁, R₁₂, and R₁₃ are all methyl groups. In another embodiment, R₁₁, R₁₂, and R₁₃ are all ethyl groups. In another embodiment, R₁₁, R₁₂, and R₁₃ are all propyl groups.

In one or more embodiments, formula (4) may be a polymer that comprises n monomer units, where n may be from 10 to 10,000,000, such as from 50 to 10,000,000, from 100 to 10,000,000, from 250 to 10,000,000, from 500 to 10,000,000, from 1,000 to 10,000,000, from 5,000 to 10,000,000, from 10,000 to 10,000,000, from 100,000 to 10,000,000, from 1,000,000 to 10,000,000, from 10 to 1,000,000, from 10 to 100,000, from 10 to 10,000, from 10 to 5,000, from 10 to 1,000, from 10 to 500, from 10 to 250, or from 10 to 100. For example, n may be from 1,000 to 1,000,000.

According to one or more embodiments, the cationic polymer comprises poly(N¹,N¹-diallyl-N¹-alkyl-N⁶,N⁶,N⁶-trialkylalkane-1,6-diamonium halide), such as poly(N¹,N¹-diallyl-N¹-methyl-N⁶,N⁶,N⁶-trialkylhexane-1,6-diamonium bromide). An example of such is PDAMAB-TPHAB, as shown in formula (1).

In another embodiment, the cationic polymer comprises poly(N¹,N¹-diallyl-N¹-methyl-N⁶,N⁶,N⁶-triethylhexane-1,6-diamonium bromide), referred to as (PDAMAB-TEHAB) and shown in formula (5).

In another embodiment, the cationic polymer poly(N¹,N¹-diallyl-N¹-methyl-N⁶,N⁶,N⁶-trimethylhexane-1,6-diamonium bromide) is referred to as (PDAMAB-TMHAB) and is shown in formula (6).

Other cationic polymers, including co-polymers, capable of acting as cationic polymer structure-directing agents have been disclosed previously. It is envisioned that such cationic polymer structure-directing agents could be used in the synthesis of the zeolites described herein.

According to one or more embodiments disclosed herein, either of the zeolites described above, hierarchical zeolites or conventional non-mesoporous zeolites, may serve as an “initial zeolite” which is then dehydroxylated, forming a dehydroxylated zeolite. In general, the initial zeolite may refer to a zeolite, which is not substantially dehydroxylated and includes at least a majority of vicinal hydroxyl groups. Dehydroxylation, as is commonly understood by those skilled in art, involves a reaction whereby a water molecule is formed by the release of a hydroxyl group and its combination with a proton. As described herein, a “dehydroxylated zeolite” refers to a zeolitic material that has been at least partially dehydroxylated (i.e., H and O atoms are liberated from the initial zeolite and water is formed). Without being bound by theory, it is believed that the dehydroxylation reaction forms a molecule of water from a hydroxyl group of a first silanol and a hydrogen of a second silanol of a zeolite. The remaining oxygen atom of the second silanol functionality forms a siloxane group in the zeolite (i.e., (≡Si—O—Si≡), sometimes referred to as a strained siloxane bridge. These strained siloxane bridges may be reactive in subsequent functionalization steps, as is described herein. Generally, strained siloxane bridges are those formed in the dehydroxylation reaction and not in the formation of the initial zeolite. The initial zeolite may primarily comprise vicinal silanol functionalities. In one or more embodiments, dehydroxylating the initial zeolite may form isolated terminal silanol functionalities comprising hydroxyl groups bonded to silicon atoms of the microporous framework of the dehydroxylated zeolite.

As described herein “silanol functionalities” refer to ≡Si—O—H groups. Silanol groups generally include a silicon atom and a hydroxyl group (—OH). As described herein, “terminal” functionalities refer to those that are bonded to only one other atom. For example, the silanol functionality may be terminal by being bonded to only one other atom such as a silicon atom of the microporous framework. As described herein, “isolated silanol functionalities” refer to silanol functionalities that are sufficiently distant from one another such that hydrogen-bonding interactions are avoided with other silanol functionalities. These isolated silanol functionalities are generally silanol functionalities on the zeolite that are non-adjacent to other silanol functionalities. Generally, in a zeolite that includes silicon and oxygen atoms, “adjacent silanols” are those that are directly bonded through a bridging oxygen atom. Those skilled in the art would understand isolated silanol functionalities may be identified by FT-IR and/or ¹H-NMR. For example, isolated silanol functionalities may be characterized by a sharp and intense FT-IR band at about 3749 cm⁻¹ and/or a ¹H-NMR shift at about 1.8 ppm. In the embodiments described herein, peaks at or near 3749 cm⁻¹ in FT-IR and/or at or near 1.8 ppm in ¹H-NMR may signify the existence of the dehydroxylated zeolite, and the lack of peaks at or near these values may signify the existence of the initial zeolite.

Isolated silanol functionalities can be contrasted with vicinal silanol functionalities, where two silanol functionalities are “adjacent” one another by each being bonded with a bridging oxygen atom. Formula (7) depicts an isolated silanol functionality and formula (8) depicts a vicinal silanol functionality. Hydrogen bonding occurs between the oxygen atom of one silanol functionality and the hydrogen atom of an adjacent silanol functionality in the vicinal silanol functionality. Vicinal silanol functionality may show a different band in FT-IR and a different ¹H-NMR shift, such as 3520 cm⁻¹ or 3720 cm⁻¹ in FT-IR, and 2.7 ppm in ¹H-NMR. It should be understood that, according to one or more embodiments presently disclosed, the various functional groups of the zeolites may be identified by FT-IR and/or ¹H-NMR methods. When a zeolite “comprises” such a moiety, such inclusion may be evidenced by a peak at or near the bands in FT-IR and/or ¹H-NMR corresponding to such moiety. Those skilled in the art would understand such detection methods.

In one or more embodiments, the initial zeolite (as well as the dehydroxylated zeolite) comprises aluminum in addition to silicon and oxygen. For example, ZSM-5 zeolite may include such atoms. In embodiments with aluminum present, the microporous framework of the dehydroxylated zeolite may include Brønsted acid silanol functionalities. In the Brønsted acid silanol functionalities, each oxygen atom of the Brønsted acid silanol functionality may bridge a silicon atom and an aluminum atom of the microporous framework. Such Brønsted acid silanol functionalities may be expressed as [≡Si—O(H)→Al≡]. In this representation, a dative bond from oxygen atom electron lone pairs to the aluminum atom is shown by the arrow. Formula (9) depicts an example of an aluminosilicate zeolite framework structure that includes the isolated terminal silanol functionalities and Brønsted acid silanol functionalities described herein.

According to one or more embodiments, the dehydroxylation of the initial zeolite may be performed by heating the initial zeolite at elevated temperatures under vacuum, such as from 700° C. to 1100° C. According to embodiments, the temperature of heating may be from 600° C. to 650° C., from 650° C. to 700° C., from 700° C. to 750° C., from 750° C. to 800° C., from 800° C. to 850° C., from 850° C. to 900° C., from 900° C. to 950° C., from 950° C. to 1000° C., from 1000° C. to 1050° C., from 1050° C. to 1100° C., or any combination of these ranges. For example, temperature ranges from 650° C. to any named value are contemplated, and temperature ranges from any named value to 1100° C. are contemplated. As described herein, vacuum pressure refers to any pressure less than atmospheric pressure. According to some embodiments, the pressure during the heating process may be less than or equal to 10⁻² mbar, less than or equal to 10^(−2.5) mbar, less than or equal to 10⁻³ mbar, less than or equal to 10^(−3.5) mbar, less than or equal to 10⁻⁴ mbar, or even less than or equal to 10^(−4.5) mbar. The heating times may be sufficiently long such that the zeolite is brought to thermal equilibrium with the oven or other thermal apparatus utilized. For example, heating times of greater than or equal to 8 hours, greater than or equal to 12 hours, or greater than or equal to 18 hours may be utilized. For example, about 24 hours of heating time may be utilized.

It is believed that according to one or more embodiments described herein, heating at temperatures below 600° C. may be insufficient to form terminal isolated silanol functionalities. However, heating at temperatures greater than 1100° C. may result in the elimination of terminal isolated silanol functionalities, or the production of such functionalities in low enough concentrations that further processing by contact with organometallic chemicals to form organometallic functionalities is not observed, as is described subsequently herein. Without being bound by any particular theory, it is believed that greater heating temperatures during dehydroxylation correlate with reduced terminal silanols present on the dehydroxylated zeolite. However, it is believed that greater heating temperatures during dehydroxylation correlate with greater amounts of strained siloxanes. For example, when the initial zeolite is heated at 700° C. during dehydroxylation, the concentration of isolated terminal silanol groups may be at least 0.4 mmol/g, such as approximately 0.45 mmol/g in some embodiments, as measured by methyl lithium titration. Dehydroxylating at 1100° C. may result in much less isolated terminal silanol and/or much less isolated Brønsted acid silanol. In some embodiments, less than 10% of the isolated terminal silanol groups present at 700° C. dehydroxylation are present when 1100° C. dehydroxylation heating is used. However, it is believed that strained siloxane groups are appreciably greater at these greater dehydroxylation temperatures.

In one or more embodiments, the dehydroxylated zeolite may be processed to form the amine-modified zeolite. Generally, to form the amine-modified zeolite, ammonia or other amine compounds, such as aniline, at an elevated temperature, may be contacted and/or reacted with the dehydroxylated zeolite. According to one or more embodiments, the temperature for the ammonia treatment may be from 200° C. to 900° C. In particular, the isolated terminal silanol functionalities may be converted to primary amine functionalities on the amine-modified zeolite. Additionally, in embodiments where aluminum is present in the zeolitic framework structure and Brønsted acid silanols are present in the dehydroxylated zeolite, a primary amine may be formed where the nitrogen atom of the primary amine is coordinated with an aluminum atom.

In one or more embodiments, isolated terminal amine functionalities may be bonded to silicon atoms of the microporous framework (sometimes referred to as silylamine groups herein). The isolated terminal amine functionalities may be primary amine functionalities such that the nitrogen atom of the primary amine functionality is bonded to two hydrogen atoms and one silicon atom of the microporous framework. Similar to the description of isolated and terminal in the context of silanol groups in the dehydroxylated zeolite, the isolated terminal amine functionalities refer to amine functionalities which are terminal by being bound to only one other atom (i.e., the silicon atom of the framework of the zeolite in this case) and are isolated by not being adjacent to other amine functionalities. In general, isolated silanol functionalities in the dehydroxylated zeolite may be converted to their corresponding isolated amine functionalities in the amine-modified zeolite.

In one or more embodiments, the amine modified zeolite may be processed to form the nickel nanoparticle functionalized zeolite. Generally, to form the nickel nanoparticle functionalized zeolite, an organometallic complex comprising a nickel atom may be contacted and/or reacted with the amine-modified zeolite. In one or more embodiments, it is believed that contacting of the amine-modified zeolite with an organometallic complex comprising a nickel atom at an appropriate temperature for an appropriate period of time may result in the formation of the nickel nanoparticle functionalized zeolite. Exemplary organometallic complexes comprising a nickel atom include, but are not limited to, bis-(1,5-cyclooctadiene)-nickel(0) (Ni[(COD)₂]), bis-(1,5-cyclooctatetraene)-nickel(0) (Ni[(COT)₂]), tris(ethylene) nickel (Ni(C₂H₄)₃), (1E,5E,9E)-cyclododeca-1,5,9-triene nickel (Ni(CDT)), Ni(η³-C₃H₅)₂, and mixtures of two or more thereof.

An exemplary reaction scheme to produce the nickel-nanoparticle functionalized zeolite from the amine-modified zeolite is shown in FIG. 1 . In particular, the isolated terminal amine functionalities may be reacted with a nickel-containing organometallic compound, such as Ni[(COD)₂] as shown, producing three isomers of cyclooctadiene as by-products. That is, in addition to the nickel-nanoparticle functionalized zeolite, 1,3-cyclooctadiene, 1,4-cyclooctadiene, and 1,5-cyclooctadiene are also produced when the nickel-containing organometallic compound is Ni[(COD)₂]. Additionally, in embodiments where aluminum is present in the zeolitic framework structure and Brønsted acid amines are present in the amine-modified zeolite, nickel nanoparticles may be associated with the zeolite framework in a manner that allows lone electron pairs of a nitrogen atom to form a coordinate bond with a nearby aluminum atom.

In embodiments, the formation of the nickel-nanoparticle functionalized zeolite from the amine-modified zeolite may be conducted at a temperature from 15° C. to 30° C., from 16° C. to 30° C., from 17° C. to 30° C., from 18° C. to 30° C., from 19° C. to 30° C., from 20° C. to 30° C., from 21° C. to 30° C., from 22° C. to 30° C., from 23° C. to 30° C., from 24° C. to 30° C., from 25° C. to 30° C., from 15° C. to 29° C., from 15° C. to 28° C., from 15° C. to 27° C., from 15° C. to 26° C., from 15° C. to 25° C., from 15° C. to 24° C., from 15° C. to 23° C., from 15° C. to 22° C., from 15° C. to 21° C., or even from 15° C. to 20° C. In embodiments, the reaction may be conducted at a temperature typically referred to as “room temperature.” That is, in embodiments, the reaction may be conduct at about 20° C. or 20 ±4° C.

In embodiments, the amine-modified zeolite may be allowed to react with the nickel-containing organometallic complex for from 30 hours to 90 hours, from 35 hours to 90 hours, from 40 hours to 90 hours, from 45 hours to 90 hours, from 50 hours to 90 hours, from 55 hours to 90 hours, from 60 hours to 90 hours, from 65 hours to 90 hours, from 70 hours to 90 hours, from 75 hours to 90 hours, from 80 hours to 90 hours, from 30 hours to 85 hours, from 30 hours to 80 hours, from 30 hours to 75 hours, from 30 hours to 70 hours, from 30 hours to 65 hours, from 30 hours to 60 hours, from 30 hours to 55 hours, from 30 hours to 50 hours, from 30 hours to 45 hours, or even from 30 hours to 40 hours. In embodiments, the amine-modified zeolite may be allowed to react with the nickel-containing organometallic complex for about 60 hours or 60±12 hours.

It is envisioned that, in various embodiments, the amine-modified zeolite may be allowed to react with the nickel-containing organometallic complex at any combination of temperature and time disclosed herein.

Reaction of the amine-modified zeolite with the nickel-containing organometallic complex may take place in a suitable solvent. Selection of the solvent is within the level of ordinary skill in the art and will be determined in view of multiple factors, such as solubility of the reactants in the solvent, intended temperature of the reaction, and like considerations. In embodiments, the solvent may be a hydrocarbon solvent such as pentane, hexane, heptane, octane, benzene, toluene, xylene, and combinations of two or more thereof. In embodiments, the solvent comprises, consists essentially of, or consists of benzene. In embodiments, the solvent may be an ethereal solvent such as diethyl ether, dimethoxy ethane, tetrahydrofuran (THF), dioxane, and combinations of two or more thereof.

In alternative embodiments, the reaction of the amine-modified zeolite with the nickel-containing organometallic complex may be solvent-free. That is, the reaction may take place in the absence of solvent. In embodiments, when all other variables are controlled, it is believed that the nickel nanoparticles produced in a solvent will be larger than those produced in accordance with the solvent-free reaction.

In one or more embodiments, the amount of Ni grafted onto the functionalized zeolite may be quantified by inductively coupled plasma atomic emission spectroscopy (ICP-AES), also referred to as inductively coupled plasma optical emission spectrometry (ICP-OES), which is an analytical technique used for the detection of chemical elements. This type of emission spectroscopy uses inductively coupled plasma to produce excited atoms and ions that emit electromagnetic radiation at wavelengths characteristic of a particular element. The plasma is a high temperature source of ionized source gas (often argon). The plasma is sustained and maintained by inductive coupling from cooled electrical coils at megahertz frequencies. The source temperature is in the range from 6000 K to 10,000 K. The intensity of the emissions from various wavelengths of light is proportional to the concentrations of the elements within the sample.

Generally, the nickel-containing organometallic functionalities may be incorporated onto the framework in a concentration from 0.1 wt % to 10 wt %, from 0.5 wt % to 10 wt %, from 0.65 wt % to 10 wt %, from 1 wt % to 10 wt %, from 1.5 wt % to 10 wt %, from 2 wt % to 10 wt %, from 2.5 wt % to 10 wt %, from 3 wt % to 10 wt %, from 3.5 wt % to 10 wt %, from 4 wt % to 10 wt %, from 4.5 wt % to 10 wt %, from 5 wt % to 10 wt %, 5.5 wt % to 10 wt %, from 6 wt % to 10 wt %, from 6.5 wt % to 10 wt %, from 7 wt % to 10 wt %, from 7.5 wt % to 10 wt %, from 8 wt % to 10 wt %, from 8.5 wt % to 10 wt %, from 9 wt % to 10 wt %, from 9.5 wt % to 10 wt %, from 0.1 wt % to 9.5 wt %, from 0.1 wt % to 9 wt %, from 0.1 wt % to 8.5 wt %, from 0.1 wt % to 8 wt %, from 0.1 wt % to 7.5 wt %, from 0.1 wt % to 7 wt %, from 0.1 wt % to 6.5 wt %, from 0.1 wt % to 6 wt %, from 0.1 wt % to 5.5 wt %, from 0.1 wt % to 5 wt %, 0.1 wt % to 4.5 wt %, from 0.1 wt % to 4 wt %, from 0.1 wt % to 3.5 wt %, from 0.1 wt % to 3 wt %, from 0.1 wt % to 2.5 wt %, from 0.1 wt % to 2 wt %, from 0.1 wt % to 1.5 wt %, from 0.1 wt % to 1 wt %, from 0.1 wt % to 0.65 wt %, or even from 0.1 wt % to 0.5 wt %. In embodiments, the nickel content may increase with increasing reaction time. For example, in certain embodiments, with a reaction time of 24 hours, the nickel content may be about 0.3 wt %, whereas with a reaction time of 60 hours, the nickel content may be about 0.65 wt %.

In embodiments, the nickel nanoparticles produced as described herein may have a particle size of greater than or equal to 3 nm. In embodiments, the particle size of the nickel nanoparticles produced thusly may be from 3 nm to 10 nm, from 3.5 nm to 10 nm, from 4 nm to 10 nm, from 4.5 nm to 10 nm, from 5 nm to 10 nm, from 5.5 nm to 10 nm, from 6 nm to 10 nm, from 6.5 nm to 10 nm, from 7 nm to 10 nm, from 7.5 nm to 10 nm, from 8 nm to 10 nm, from 8.5 nm to 10 nm, from 9 nm to 10 nm, from 9.5 nm to 10 nm, from 3 nm to 9.5 nm, from 3 nm to 9 nm, from 3 nm to 8.5 nm, from 3 nm to 8 nm, from 3 nm to 7.5 nm, from 3 nm to 7 nm, from 3 nm to 6.5 nm, from 3 nm to 6 nm, from 3 nm to 5.5 nm, from 3 nm to 5 nm, from 3 nm to 4.5 nm, from 3 nm to 4 nm, or even from 3 nm to 3.5 nm.

In one or more embodiments, the presently disclosed functionalized zeolites may be suitable for use as catalysts in refining, petrochemicals, and chemical processing. For example, zeolites may be useful as cracking catalysts in processes such as hydrocracking or fluid catalytic cracking. Table 1 shows some contemplated catalytic functionality for the presently disclosed functionalized zeolites, and provides the type of zeolite that may be desirable. However, it should be understood that the description of Table 1 should not be construed as limiting on the possible uses for functionalized zeolites presently disclosed.

TABLE 1 Catalytic functions of described functionalized zeolites Framework of zeolite components Catalytic Reaction Target Description of catalyst Catalytic cracking To convert high boiling, high FAU, MFI molecular mass hydrocarbon fractions to more valuable gasoline, olefinic gases, and other products Hydrocracking To produce diesel with higher FAU, BEA quality Gas oil Maximizing production of premium FAU, MFI hydrotreating/Lube distillate by catalytic dewaxing hydrotreating Alkane cracking To improve octane and production MFI and alkylation of of gasolines and BTX aromatics Olefin To convert light olefins to FER, MFI oligomerization gasoline & distillate Methanol To produce light olefins from CHA, MFI dehydration methanol to olefins Heavy aromatics To produce xylene from C9+ MFI, FAU transalkylation Fischer-Tropsch To produce gasoline, hydrocarbons, MFI Synthesis FT and linear alpha-olefins, mixture of oxygenates CO₂ to fuels To make organic chemicals, MFI and chemicals materials, and carbohydrates

According to additional embodiments, the presently disclosed functionalized zeolites may be suitable for use in separation and/or mass capture processes. For example, the presently disclosed functionalized zeolites may be useful for adsorbing CO₂ and for separating p-xylene from its isomers.

According to an aspect, either alone or in combination with any other aspect, a functionalized fibrous hierarchical zeolite includes a framework comprising aluminum atoms, silicon atoms, and oxygen atoms, the framework further comprising a plurality of micropores and a plurality of mesopores. The functionalized fibrous hierarchical zeolite is functionalized with at least one amine. A plurality of nanoparticles comprising nickel are immobilized on the framework.

According to a second aspect, either alone or in combination with any other aspect, one or more of the at least one amine forms a dative bond with one or more of the aluminum atoms of the framework.

According to a third aspect, either alone or in combination with any other aspect, one or more of the at least one amine associates with the nanoparticles comprising nickel, thereby immobilizing the nanoparticles comprising nickel.

According to a fourth aspect, either alone or in combination with any other aspect, the framework is selected from the group consisting of an MFI, an FAU, a BEA, an MOR, and a combination of two or more thereof.

According to a fifth aspect, either alone or in combination with any other aspect, the framework is an MFI.

According to a sixth aspect, either alone or in combination with any other aspect, the nanoparticles comprising nickel have an average particle size from 3 nm to 7 nm.

According to a seventh aspect, either alone or in combination with any other aspect, the nanoparticles comprising nickel have an average particle size from 4.5 nm to 5 nm.

According to an eighth aspect, either alone or in combination with any other aspect, a method for making a functionalized fibrous hierarchical zeolite comprising a plurality of nanoparticles comprising nickel includes contacting a fibrous hierarchical zeolite with an organometallic complex comprising a nickel atom. The fibrous hierarchical zeolite includes a framework comprising aluminum atoms, silicon atoms, and oxygen atoms, the framework further comprising a plurality of micropores and a plurality of mesopores, the fibrous hierarchical zeolite being functionalized with at least one amine. The nanoparticles comprising nickel are immobilized on the framework. The contacting of the fibrous hierarchical zeolite with the organometallic complex forms the functionalized fibrous hierarchical zeolite comprising a plurality of nanoparticles comprising nickel.

According to a ninth aspect, either alone or in combination with any other aspect, one or more of the at least one amine forms a dative bond with one or more of the aluminum atoms of the framework.

According to a tenth aspect, either alone or in combination with any other aspect, one or more of the at least one amine associates with the nanoparticles comprising nickel, thereby immobilizing the nanoparticles comprising nickel.

According to an eleventh aspect, either alone or in combination with any other aspect, the framework is selected from the group consisting of an MFI, an FAU, a BEA, an MOR, and a combination of two or more thereof.

According to a twelfth aspect, either alone or in combination with any other aspect, the framework is an MFI.

According to a thirteenth aspect, either alone or in combination with any other aspect, the organometallic complex is selected from the group consisting of Ni(COD)₂, Ni(COT)₂, Ni(C₂H₄)₃, Ni(CDT), Ni(η³-C₃H₅)₂, and a combination of two or more thereof.

According to a fourteenth aspect, either alone or in combination with any other aspect, the organometallic complex is Ni(COD)₂.

According to a fifteenth aspect, either alone or in combination with any other aspect, the contacting takes place at a temperature from 15° C. to 25° C.

According to a sixteenth aspect, either alone or in combination with any other aspect, the contacting takes place for from 40 hours to 80 hours.

EXAMPLES

The various embodiments of methods and systems for forming functionalized zeolites will be further clarified by the following examples. The examples are illustrative in nature and should not be understood to limit the subject matter of the present disclosure.

Example 1 Synthesis of Mesoporous ZSM-5 Zeolite

A mesoporous ZSM-5 zeolite was formed having a Si/Al molar ratio of 30. In a typical synthesis, a homogeneous solution was prepared by dissolving 0.75 g of NaOH and 0.21 g of NaAlO₂ in 59.0 g of deionized water. This was followed by the addition 2.0 g of PDAMAB-TPHAB polymer under vigorous stirring at 60° C. After stirring for 1 hour, 16.5 g of tetraethyl orthosilicate (TEOS) was added dropwise to the solution and further stirred for 12 hours at 60° C. The obtained viscous gel was subjected to hydrothermal treatment at 150° C. for 60 hours. The resulting solids were washed, filtered and dried at 110° C. for overnight. The as-synthesized solids were calcined at 550° C. for 6 hours at a heating rate of 1° C./min under static conditions. Then, an ion-exchange procedure was performed using 1.0 M NH₄NO₃ solution at 80° C. The ion-exchanging process was repeated thrice prior to calcination at 550° C. for 4 hours in air to generate the H-form of ZSM-5 zeolite.

Example 2 Synthesis of a ZSM-5 Zeolite Dehydroxylated at 700° C.

A dehydroxylated ZSM-5 zeolite was formed by treating 2 g of the mesoporous ZSM-5 zeolite of Example 1 at a temperature of 700° C. and a pressure of 10⁻⁵ mbar for a time of 20 hours. Heating occurred at a rate of 150° C./hr.

Example 3 Synthesis of an Amine Modified ZSM-5 Zeolite

The dehydroxylated ZSM-5 zeolite of Example 2 was treated with ammonia at a temperature of 500° C. for 6 hours to produce an amine-modified ZSM-5 zeolite.

Example 4 Synthesis of a Nickel-Nanoparticle Functionalized Amine-Modified ZSM-5 Zeolite

The amine modified ZSM-5 zeolite of Example 3 (0.0945 mmol of —NH₂ concentration, 1 equiv.) was introduced to a first compartment of a double schlenk flask under an argon atmosphere in a glove box. A solution of Ni[(COD)₂] (0.0378 mmol, 0.4 equiv.) was added to the second compartment of the double schlenk flask in dry, degassed benzene (10 mL) at room temperature. The Ni[(COD)₂] solution was transferred to the first compartment, and the reaction mixture was stirred at room temperature for 60 hours, which led to the formation of a gray solid material identified as the desired nickel-nanoparticle functionalized amine modified ZSM-5 zeolite. The solid material was isolated from the liquid phase and was washed with dry benzene (3×10 mL) to eliminate unreacted Ni[(COD)₂]. Finally, the solid material, the nickel-nanoparticle functionalized amine-modified ZSM-5 zeolite, was dried at 80° C. under dynamic vacuum (10⁻⁵ mbar) overnight. The resulting material was stored in a glove box. The ICP-AES indicated that the nickel-nanoparticle functionalized amine-modified ZSM-5 zeolite had a nickel content of 0.65 wt %. The magic angle spinning (MAS) ²⁷Al solid state NMR spectrum of the nickel-containing organometallic functionalized ZSM-5 zeolite (10), FIG. 2 , shows a characteristic peak at 53.83 ppm. The average particle size of the nickel-nanoparticles was found to be 4.8 nm, in accordance with electron microscopy. High-resolution transmission electron microscopy (HR-TEM) of the samples was performed with a Titan ThemisZ microscope from Thermo-Fisher Scientific, equipped with a spherical aberration corrector for the electron beam and an energy-dispersive spectroscopy (EDS) detector. The microscope was operated at an accelerating voltage of 300 kV. The particles could be seen directly from the EM micrographs The particle size distribution is shown in FIG. 3 .

The microscopic observations of the nickel-nanoparticle functionalized amine-modified ZSM-5 zeolite were performed under an inert atmosphere using scanning transmission electron microscopy (HAADF-STEM) and are shown in FIG. 4 . This experiment confirms the presence of nickel, carbon, and nitrogen, which are displayed on the surface of the nickel-nanoparticle functionalized amine-modified ZSM-5 zeolite. Transmission electron microscopy (TEM) and scanning TEM (STEM) investigations were performed with a ThermoFisher FEI Titan 80-300 Cubed microscope equipped with a high-brilliance field emission gun (300 kV), a Wien-type FEI monochromator, chemiSTEM™ technology for energy dispersive X-ray spectroscopy (EDX), and a CEOS spherical aberration probe corrector (for the condenser lens system) allowing a final resolution of 0.9 Å in STEM mode. The TEM samples were fully prepared in a glove box under an argon inert atmosphere to avoid any alteration reaction due to the exposure to the air and then transferred directly into a Gatan 618 double-tilt vacuum transfer holder. In that way, the samples were never exposed to the air from the synthesis to the analysis.

X-ray photoelectron spectroscopy (XPS) of the nickel-nanoparticle functionalized ZSM-5 zeolite is shown in FIG. 5 . In XPS, the nickel oxidation states can be analyzed from the binding energies (BE) and the chemical shift of the Ni 2p photoelectron lines in XPS spectra. The spectrum recorded for the nickel-nanoparticle functionalized ZSM-5 zeolite (FIG. 5 ) reveals the presence of a main peak with similar binding energy of 852.1 eV. This peak is attributed to the primary photoelectron lines of 2p_(3/2) for the Ni(0) oxidation state. The XPS experiments were performed on a Kratos Axis Ultra DLD instrument equipped with a monochromatic Al Kα x-ray source (hv=1486.6 eV) operated at a power of 75 W and under UHV conditions in the range of ˜10⁻⁹ mbar. All spectra were recorded in hybrid mode using electrostatic and magnetic lenses and an aperture slot of 300 μm×700 μm. The survey and high-resolution spectra were acquired at fixed analyzer pass energies of 160 eV and 20 eV, respectively. The samples were mounted in floating mode in order to avoid differential charging. Therefore, XPS spectra were acquired using charge neutralization. Because the samples are air-sensitive, they were transferred to the XPS instrument and analyzed without exposing them to the ambient air. For this purpose, samples were first prepared inside the glovebox always kept under argon atmosphere and were subsequently transferred to the XPS instrument using a special transfer chamber filled with argon prior to be sealed. The samples were promptly analyzed after being loaded into the instrument.

High-resolution transmission electron microscopy (HR-TEM) images, FIG. 6 , of the nickel-nanoparticle functionalized ZSM-5 zeolite clearly show the lattice fringes originating from the MFI framework, which remains unchanged from the dehydroxylated ZSM-5 zeolite.

Having described the subject matter of the present disclosure in detail and by reference to specific embodiments, it is noted that the various details described in this disclosure should not be taken to imply that these details relate to elements that are essential components of the various embodiments described in this disclosure, even in cases where a particular element is illustrated in each of the drawings that accompany the present description. Rather, the claims appended hereto should be taken as the sole representation of the breadth of the present disclosure and the corresponding scope of the various embodiments described in this disclosure. Further, it will be apparent that modifications and variations are possible without departing from the scope of the appended claims.

The singular forms “a”, “an” and “the” include plural referents, unless the context clearly dictates otherwise.

For the purposes of describing and defining the present disclosure it is noted that the term “about” is utilized in this disclosure to represent the inherent degree of uncertainty that may be attributed to any quantitative comparison, value, measurement, or other representation. The term “about” is also utilized in this disclosure to represent the degree by which a quantitative representation may vary from a stated reference without resulting in a change in the basic function of the subject matter at issue.

As used in this disclosure and in the appended claims, the words “comprise,” “has,” and “include” and all grammatical variations thereof are each intended to have an open, non-limiting meaning that does not exclude additional elements or steps.

Additionally, the term “consisting essentially of” is used in this disclosure to refer to quantitative values that do not materially affect the basic and novel characteristic(s) of the disclosure. For example, a chemical stream “consisting essentially” of a particular chemical constituent or group of chemical constituents should be understood to mean that the stream includes at least about 99.5% of a that particular chemical constituent or group of chemical constituents.

It should be understood that any two quantitative values assigned to a property may constitute a range of that property, and all combinations of ranges formed from all stated quantitative values of a given property are contemplated in this disclosure.

As used in this disclosure, terms such as “first” and “second” are arbitrarily assigned and are merely intended to differentiate between two or more instances or components. It is to be understood that the words “first” and “second” serve no other purpose and are not part of the name or description of the component, nor do they necessarily define a relative location, position, or order of the component. Furthermore, it is to be understood that the mere use of the term “first” and “second” does not require that there be any “third” component, although that possibility is contemplated under the scope of the present disclosure. 

1. A functionalized fibrous hierarchical zeolite comprising a framework comprising aluminum atoms, silicon atoms, and oxygen atoms, the framework further comprising a plurality of micropores and a plurality of mesopores, wherein: the functionalized fibrous hierarchical zeolite is functionalized with at least one amine, and a plurality of nanoparticles comprising nickel are immobilized on the framework.
 2. The functionalized fibrous hierarchical zeolite of claim 1, wherein one or more of the at least one amine forms a dative bond with one or more of the aluminum atoms of the framework.
 3. The functionalized fibrous hierarchical zeolite of claim 1, wherein one or more of the at least one amine associates with the nanoparticles comprising nickel, thereby immobilizing the nanoparticles comprising nickel.
 4. The functionalized fibrous hierarchical zeolite of claim 1, wherein the framework is selected from the group consisting of an MFI, an FAU, a BEA, an MOR, and a combination of two or more thereof.
 5. The functionalized fibrous hierarchical zeolite of claim 1, wherein the framework is an MFI.
 6. The functionalized fibrous hierarchical zeolite of claim 1, wherein the nanoparticles comprising nickel have an average particle size from 3 nm to 7 nm.
 7. The functionalized fibrous hierarchical zeolite of claim 1, wherein the nanoparticles comprising nickel have an average particle size from 4.5 nm to 5 nm.
 8. A method for making a functionalized fibrous hierarchical zeolite comprising a plurality of nanoparticles comprising nickel, the method comprising: contacting a fibrous hierarchical zeolite with an organometallic complex comprising a nickel atom, wherein the fibrous hierarchical zeolite comprises: a framework comprising aluminum atoms, silicon atoms, and oxygen atoms, the framework further comprising a plurality of micropores and a plurality of mesopores, the fibrous hierarchical zeolite being functionalized with at least one amine; wherein the nanoparticles comprising nickel are immobilized on the framework, and the contacting of the fibrous hierarchical zeolite with the organometallic complex forms the functionalized fibrous hierarchical zeolite comprising a plurality of nanoparticles comprising nickel.
 9. The method of claim 8, wherein one or more of the at least one amine forms a dative bond with one or more of the aluminum atoms of the framework.
 10. The method of claim 8, wherein one or more of the at least one amine associates with the nanoparticles comprising nickel, thereby immobilizing the nanoparticles comprising nickel.
 11. The method of claim 8, wherein the framework is selected from the group consisting of an MFI, an FAU, a BEA, an MOR, and a combination of two or more thereof.
 12. The method of claim 8, wherein the framework is an MFI.
 13. The method of claim 8, wherein the organometallic complex is selected from the group consisting of Ni(COD)₂, Ni(COT)₂, Ni(C₂H₄)₃, Ni(CDT), Ni(η³-C₃H₅)₂, and a combination of two or more thereof.
 14. The method of claim 8, wherein the organometallic complex is Ni(COD)₂.
 15. The method of claim 8, wherein the contacting takes place at a temperature from 15° C. to 25° C.
 16. The method of claim 8, wherein the contacting takes place for from 40 hours to 80 hours. 